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Equation of state in (2+1)-flavor QCD with gradient flow

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 نشر من قبل Kazuyuki Kanaya
 تاريخ النشر 2016
  مجال البحث
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The energy-momentum tensor and equation of state are studied in finite-temperature (2+1)-flavor QCD with improved Wilson quarks using the method proposed by Makino and Suzuki based on the gradient flow. We find that the results of the gradient flow are consistent with the previous results using the $T$-integration method at $T mathrel{rlap{raise 0.511ex hbox{$<$}}{lower 0.511ex hbox{$sim$}}} 280$ MeV ($N_tmathrel{rlap{raise 0.511ex hbox{$>$}}{lower 0.511ex hbox{$sim$}}}10$), while a disagreement is found at $T mathrel{rlap{raise 0.511ex hbox{$>$}}{lower 0.511ex hbox{$sim$}}} 350$ MeV ($N_t mathrel{rlap{raise 0.511ex hbox{$<$}}{lower 0.511ex hbox{$sim$}}} 8$) presumably due to the small-$N_t$ lattice artifact. We also report on the results on the renormalized chiral condensate and its disconnected susceptibility using the method of Hieda and Suzuki. The results show a clear signal of the expected chiral restoration crossover even with Wilson-type quarks which violate the chiral symmetry explicitly.



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